Abstract 983: Antibody-drug conjugates of NAMPT inhibitors: Discovery, optimization, and preclinical characterization

C. Neumann, K. Olivas, K. Wang, A. Waight, David W Meyer, Luke V Loftus, Margo Zaval, Martha E. Anderson, Steven Jin, Julia H Cochran, J. Simmons, Paul G Pittman, Fu Li, Michelle Ulrich, Abbie Wong, Weiping Zeng, R. Lyon, P. Senter
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Abstract

Nicotinamide phosphoribosyltransferase (NAMPT) regulates the biosynthesis of NAD from nicotinamide via a salvage biosynthetic pathway. Inhibition of NAMPT depletes cellular NAD levels leading to disruption of energy metabolism and cell death. Non-targeted small molecule NAMPT inhibitors have demonstrated poor tolerability in clinical trials and in preclinical models, including cardiac and retinal toxicities in rats. In an effort to improve the therapeutic window of this drug class, we pursued a targeted-delivery approach using antibody-drug conjugates. Through a medicinal chemistry effort, we identified novel NAMPT inhibitors that incorporate chemical functionality in the solvent-exposed terminus to allow construction of enzyme-cleavable drug linkers. Additionally, we applied a pyridinium-based linker strategy that allows for traceless linker attachment through a conserved nicotinamide-mimetic moiety of NAMPT inhibitors. Candidate molecules were evaluated for NAMPT binding affinity and cellular cytotoxicity as free drugs, and for cellular cytotoxicity as ADCs with the alternate linker strategies. Comparisons across inhibitors and linker strategies provide insight into optimal design of cleavable drug linkers for this class of drugs. In vitro, the ADCs deplete NAD and lead to downstream ATP depletion in a time-dependent manner. In vivo evaluation using human tumor xenografts shows translation of the pharmacodynamic effect resulting in tumor regression in models of Hodgkin lymphoma, non-Hodgkin lymphoma, and acute myeloid leukemia. Toxicology studies in Sprague Dawley rats demonstrate excellent tolerability at active doses, with no observable cardiac or retinal toxicities at the highest tested doses in single- and multi-dose regimens. These findings detail the development of a novel payload class and optimized linker strategy for use with antibody-drug conjugates, and demonstrate a preclinical efficacy and safety profile to support continued efforts toward clinical therapeutics. Citation Format: Chris Neumann, Kathleen C. Olivas, Kung Pern Wang, Andrew B. Waight, David W. Meyer, Luke V. Loftus, Margo C. Zaval, Martha E. Anderson, Steven Jin, Julia H. Cochran, Jessica K. Simmons, Paul G. Pittman, Fu Li, Michelle L. Ulrich, Abbie Wong, Weiping Zeng, Robert P. Lyon, Peter D. Senter. Antibody-drug conjugates of NAMPT inhibitors: Discovery, optimization, and preclinical characterization [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 983.
摘要:NAMPT抑制剂的抗体-药物偶联物:发现、优化和临床前表征
烟酰胺磷酸核糖基转移酶(NAMPT)通过补救性生物合成途径调节烟酰胺NAD的生物合成。抑制NAMPT会耗尽细胞NAD水平,导致能量代谢中断和细胞死亡。非靶向小分子NAMPT抑制剂在临床试验和临床前模型中表现出较差的耐受性,包括大鼠的心脏和视网膜毒性。为了改善这类药物的治疗窗口期,我们采用了一种使用抗体-药物偶联物的靶向递送方法。通过药物化学的努力,我们发现了新的NAMPT抑制剂,在溶剂暴露的末端结合化学功能,允许构建酶可切割的药物连接物。此外,我们应用了基于吡啶的连接策略,该策略允许通过NAMPT抑制剂的保守的烟酰胺模拟部分进行无迹连接。候选分子作为游离药物评估了NAMPT结合亲和力和细胞毒性,以及作为adc使用替代连接策略评估了细胞毒性。跨抑制剂和连接策略的比较为这类药物的可切割药物连接的最佳设计提供了见解。在体外,adc以时间依赖性的方式消耗NAD并导致下游ATP消耗。使用人类肿瘤异种移植物的体内评估显示,在霍奇金淋巴瘤、非霍奇金淋巴瘤和急性髓性白血病模型中,药效学效应的翻译导致肿瘤消退。在Sprague Dawley大鼠中进行的毒理学研究表明,在活性剂量下具有良好的耐受性,在单剂量和多剂量方案的最高测试剂量下,没有观察到心脏或视网膜毒性。这些发现详细介绍了一种新的有效载荷类别和优化的抗体-药物偶联物连接策略的发展,并证明了临床前的有效性和安全性,以支持临床治疗的持续努力。引文格式:Chris Neumann, Kathleen C. Olivas, Kung Pern Wang, Andrew B. Waight, David W. Meyer, Luke V. Loftus, Margo C. Zaval, Martha E. Anderson, Steven Jin, Julia H. Cochran, Jessica K. Simmons, Paul G. Pittman,傅莉,Michelle L. Ulrich, Abbie Wong,曾卫平,Robert P. Lyon, Peter D. Senter。NAMPT抑制剂的抗体-药物偶联物:发现、优化和临床前表征[摘要]。摘自:2019年美国癌症研究协会年会论文集;2019年3月29日至4月3日;亚特兰大,乔治亚州。费城(PA): AACR;癌症杂志,2019;79(13增刊):摘要第983期。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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